)
)
)
)
)
)
)
)
)
Marco Papagno,†,‡,* Daniela Pacile´,†,‡ Dinesh Topwal,§,^ Paolo Moras,† Polina Makarovna Sheverdyaeva,† Fabian Donat Natterer, Anne Lehnert, Stefano Rusponi, Quentin Dubout, Fabian Calleja, Emmanouil Frantzeskakis, Ste´phane Pons, ,# Jun Fujii,4 Ivana Vobornik,4 Marco Grioni, Carlo Carbone,† and Harald Brune
ARTICLE
Two Distinct Phases of Bilayer Graphene Films on Ru(0001) Istituto di Struttura della Materia, Consiglio Nazionale delle Ricerche, Trieste, Italy, ‡Dipartimento di Fisica, Universitá della Calabria, 87036 Arcavacata di Rende (Cs), Italy, §International Center for Theoretical Physics, Trieste, Italy, ^CSIR-Central Glass and Ceramic Research Institute, 196, S.C. Raja Mullick Road, Kolkata700032, India, Institute of Condensed Matter Physics, Ecole Polytechnique Fédérale de Lausanne, CH-1015 Lausanne, Switzerland, #Institut des NanoSciences de Paris, Université Pierre et Marie Curie, CNRS UMR 7588, France, and 4CNR-IOM, TASC Laboratory, Basovizza, Trieste, Italy )
†
T
he peculiar electronic properties of graphene result from its twodimensional (2D) honeycomb crystal lattice.1�6 This 2D structure makes every carbon atom a surface atom and thus strongly exposed to the surrounding environment. The simple act of resting on a substrate may modify the electronic band structure and cause a precipitous decline of its charge carrier mobility.5,8�10 For example, when graphene is placed on top of another graphene layer in a Bernal (ABAB) stacking, the coupling between the planes modifies the linear dispersion of the massless charge carriers into a hyperbolic dispersion of massive chiral fermions.11,12 The graphene layers can be partially decoupled by misorienting them by more than 20�13 or by an AA stacking sequence.14,15 In these cases, the band structure has been predicted to be the superposition of two single-layer bands of freestanding graphene, and only states with a linear dispersion close to the Fermi level in proximity to the K points are present. Yet another way to preserve the electronic properties of graphene is to adsorb it on a material that has only a very weak interaction with graphene. Recently, graphene supported on a hexagonal boron nitride substrate16 showed electrical properties comparable to that of freestanding graphene. On SiC(0001)7,17,18 and on Ni19�21 the first graphene layer saturates the substrate bonds and allows the synthesis of subsequent graphene layers with nearly freestanding character. Another surface that strongly modifies graphene properties is Ru(0001). In this case, the first graphene layer relieves the strain due to the lattice mismatch between PAPAGNO ET AL.
ABSTRACT
By combining angle-resolved photoemission spectroscopy and scanning tunneling microscopy we reveal the structural and electronic properties of multilayer graphene on Ru(0001). We prove that large ethylene exposure allows the synthesis of two distinct phases of bilayer graphene with different properties. The first phase has Bernal AB stacking with respect to the first graphene layer and displays weak vertical interaction and electron doping. The longrange ordered moiré pattern modulates the crystal potential and induces replicas of the Dirac cone and minigaps. The second phase has an AA stacking sequence with respect to the first layer and displays weak structural and electronic modulation and p-doping. The linearly dispersing Dirac state reveals the nearly freestanding character of this novel second-layer phase. KEYWORDS: multilayer graphene . Ru . stacking sequence . photoemission . STM
graphene and the substrate by developing a (23 � 23) moiré structure.22 Core level spectroscopy,23 scanning tunneling microscopy (STM),22,24�28 and density functional theory calculations24,27�31 have revealed spatial inhomogeneities in the charge density reflecting regions with varying graphene� substrate hybridization. Angle-resolved photoemission spectroscopy (ARPES) studies displayed a single and broad π band with a relatively large gap.31 The first graphene layer saturates the metal bonds and acts as a VOL. 6
’
NO. 10
’
* Address correspondence to marco.papagno@fis.unical.it. Received for review August 21, 2012 and accepted September 28, 2012. Published online September 28, 2012 10.1021/nn303821w C 2012 American Chemical Society
9299–9304
’
2012
9299 www.acsnano.org
ARTICLE Figure 1. (a) Second derivative of the ARPES intensity map along the ΓK direction of graphene for the low-exposure sample. π1 and π2C label the electronic states of the first monolayer and of the corrugated second monolayer graphene, respectively. The broad feature enclosed by white crosses is ascribed to the π*1 state strongly modified by the substrate interaction. Due to marginal electron doping of the corrugated layer, we observe also the π*2C state. (b) Raw and (c) second-derivative ARPES intensity maps for the high-exposure sample. π2F identifies a new electronic state of the second monolayer. (d) Energy distribution curves from the spectra enclosed by the red rectangle in panel (b). Δ labels the electronic gap between the π2C and π*2C states.
template for the growth of a subsequent graphene layer with freestanding character,32,33 which displays a sharp and linearly dispersing Dirac cone.34 Here, we provide evidence of a novel second-layer phase on Ru(0001), which arises after exposure to more than 105 L of ethylene that coexists with the hitherto reported phase. We compare ARPES data of the two second-layer phases and find that the new phase gives rise to a second linearly dispersing π band, which is shifted with respect to that of the first phase due to significant p-doping. Our STM data reveal that the two second-layer phases have different stacking sequences and moiré amplitudes. RESULTS AND DISCUSSION Figure 1a displays the second derivative of the ARPES intensity map along the ΓK direction of the graphene Brillouin zone after exposure to 102 L of ethylene. We reproduce the previously observed relatively broad π1 and π*1 bands and the sharp π2C and π*2C states. In addition, we identify replica bands associated with the π2C and σ states. In accordance with literature,34 we assign the bands as follows. The monolayer interacts strongly with the underlying substrate and displays a parabolic-like dispersion of the π state31,34,35 (π1 band). This band has the minimum at E � EF = �10.1 eV at the Γ point and the maximum at E � EF = �4 eV at the K point. The strong interaction with the substrate also modifies the π*1 into a diffuse and faint band (enclosed by the white crosses in Figure 1a) in proximity to the Fermi level. The first layer saturates the metal orbitals and allows the growth of a second graphene layer, which exhibits a sharp and n-doped π2C Dirac cone, with the Dirac point at 0.45 ( 0.05 eV below EF, along with replica and σ bands.32�35 PAPAGNO ET AL.
As will become clear from the STM data presented below, we refer to this layer as a corrugated layer, therefore the label C. Figure 1b and c show raw and second-derivative ARPES maps recorded after exposing the 102 L surface to a further 105 L of ethylene. In addition to the first and corrugated second monolayer bands, we find a new π state, which we call π2F. F stands for flat layer, see below. The main features of this state are better captured in Figure 1d, which displays energy distribution curves (EDCs) of the region marked by the red rectangle in Figure 1b. The π2F state disperses upward parallel to the π2C state and crosses the Fermi level before the maximum is reached, reminiscent of p-doping. By extrapolation of its linear dispersion we estimate the maximum of this band at 0.60 ( 0.05 eV above the Fermi level. The constant dE/dk gradient confirms the nearly free character of the layers and yields an electron group velocity of vg = (1.0 ( 0.1) � 106 m/s for both bands. Furthermore, EDC spectra highlight an electronic gap Δ between the π2C and π*2C states of 200 ( 30 meV at the K point (blue curve). This gap is also observed in the 102 L sample at variance with earlier measurements.34,35 Figure 2 presents constant-energy maps close to the K point of the graphene Brillouin zone and acquired on the low-exposure (Figure 2a�d) and high-exposure samples (Figure 2e�h). The Fermi surface of the 102 L sample displays the Dirac-like electron pocket of the π2C state centered at the K point and surrounded by hexagonally arranged replicas (Figure 2a, b). The excellent long-range order of the surface allows to observe up to the third replica and to accurately measure the spacing between the replicas, amounting to 0.24 ( 0.02 Å�1. The electron density estimated from VOL. 6
’
NO. 10
’
9299–9304
’
9300
2012 www.acsnano.org
ARTICLE Figure 2. (a) Constant-energy maps of graphene states and (b) close-up of the K point for the 102 L sample at E � EF = 0. Panels (c) and (d) display underlying bands for E � EF = �0.3 and �0.8 eV, respectively. (e) Fermi surface of graphene bands (f) and zoom-in around the K point for the 105 L sample. Panels (g) and (h) show the constant energy maps measured at E � EF = �0.3 and �0.8 eV. Red lines in (a) and (e) mark the limits of the first Brillouin zone of graphene.
the relative size of the graphene Fermi surface with respect to the surface of the Brillouin zone of graphite is 0.9 � 1013 cm�2. For E � EF = �0.3 eV (Figure 2c), graphene bands are point-like and then display hole pockets for E � EF < �0.6 eV (Figure 2d). Similarly to graphene on SiC(0001),5 these replicas could be induced by diffraction effects due to the moiré of the first graphene layer34 or, as discussed later in the text, to the superlattice potential of the second graphene layer. The Fermi surface of the 105 L sample in Figure 2e and f shows an additional Dirac-like hole pocket due to the π2F band coexisting with the bands of the corrugated layer. The charge carrier concentration estimated from the relative size of the π2F hole pocket is 2.5 � 1013 holes per cm�2. With decreasing energies (Figure 2g, h) the π2F state spreads out in k-space without affecting the π2C state. It is evident from comparison of the constant-energy maps of both samples that the features of the 102 L sample appear at the same energies and positions in k-space also on the 105 L sample. Therefore the additional π2F feature exhibited by the 105 L sample coexists but does not interact with the π2C features. This is a notable difference with respect to multilayer graphene, where the number of π bands increases with the number of layers, but their dispersion gets modified by interlayer coupling.5,34 The absence of this interlayer coupling in the present case strongly suggests the coexistence of two second-layer phases rather than the coexistence of second and a third monolayer. This conjecture is unequivocally proven PAPAGNO ET AL.
by the following STM results recorded on a sample for which identical ARPES results with the ones shown in Figure 2e�h have been obtained. Figure 3a shows an STM image of the 105 L sample. The Ru surface is entirely covered by a well-ordered graphene first layer. This layer displays the (23 � 23) moiré pattern22,23,31,32,34 resulting from the lattice mismatch between Ru and graphene.22,26,36 Part of the first layer is covered by second-layer graphene. On large-scale images we clearly discern two types of second layer by their different moiré corrugation. A patch of the second-layer type already reported in literature33 is visible in the lower left part of the image. It displays a moiré pattern with a maximum corrugation of 1.10 ( 0.05 Å. It is therefore referred to as a corrugated (C) layer and covers 12 ( 2% of the surface. The second type of the second layer is visible on the right-hand side of Figure 3a. It covers 25 ( 5% of the first layer. Panel (c) shows that the 2F layer is essentially flat compared to the first monolayer. The STM image in Figure 3d shows the weak moiré contrast of the 2F layer. The apparent height amplitudes of the moiré patterns of the first and 2F layers are 1.30 ( 0.05 and 0.05 ( 0.02 Å, respectively. The line profile in Figure 3b demonstrates that 2C and 2F further distinguish themselves by their apparent heights with respect to the monolayer of 3.3 ( 0.1 and 2.1 ( 0.1 Å, respectively. The apparent height of a Ru(0001) step is 2.2 ( 0.1 Å, in agreement with the literature value of 2.14 Å. The value measured for 2C corresponds to the distance of 3.3 Å between the atomic layers in graphite, which is Bernal, i.e., AB VOL. 6
’
NO. 10
’
9299–9304
’
9301
2012 www.acsnano.org
stacked.33,37 The AB stacking breaks the graphene sublattice symmetry, while the AA stacking does not. Therefore high-resolution STM data can discern the two stackings, as evidenced by Figure 3e and f with their line profiles. In Figure 3e the protrusions mark the centers of the C6 rings and the two carbon atoms per graphene unit cell are imaged as dark spots; the line profile taken along the blue line and displayed in Figure 3g evidences a difference in apparent height of 25 ( 6 pm between these two atoms (vertical dotted line). This lifting of the degeneracy between the A and PAPAGNO ET AL.
VOL. 6
’
NO. 10
’
9299–9304
’
ARTICLE
Figure 3. (a) Constant-current STM image of graphene on Ru(0001) (ethylene exposure 105 L, Vt = �3 V; It = 75 pA; T = 4 K; size 2320 Å � 283 Å). 1, 2C, and 2F stand for first layer and second corrugated and flat layer, respectively. (b) Apparent height profile along the red line displayed in (a). (c) Constant-current STM image of a sample region with coexisting first graphene layer and 2F layer (Vt = �3 V; It = 75 pA; T = 4 K; size 762 Å � 762 Å). (d) STM image of the 2F island (Vt = �1 V; It = 100 pA; T = 4 K; size = 391 Å � 391 Å) showing a very weak moiré pattern. (e) High-resolution STM image for 2C (Vt = �0.1 V; It = 200 pA; T = 4 K; size 25 Å � 25 Å) and (f) 2F (Vt = �0. V; It = 100 pA; T = 4 K; size 25 Å � 25 Å). Note that the STM tip gives with respect to the atomic geometry a reversed contrast with C atoms imaged as dark spots. Red hexagons mark the graphene honeycomb lattice. (g and h) Apparent height profiles along the blue and green lines displayed in (e) and (f), respectively. Dotted and continuous vertical bars in (g) and (h) highlight the difference in the apparent height between carbon atoms with different sublattice symmetry for the 2C and 2F layers, respectively.
B sublattices takes place in all the investigated regions of the corrugated layer and is responsible for the band gap Δ between the π2C and π*2C states observed in Figure 1. The apparent height between the first and the 2F layer is considerably smaller than the interlayer distance in graphite. However, in a previous STM work an apparent height of 2.5 Å has been observed between the first and the second graphene layer on SiC.38 Highresolution transmission electron microscope studies reported a distance of 2.2 Å between two graphene layers grown on the (111) surface of diamond.39 This relatively small interlayer distance has been explained by an AA0 stacking, where alternate planes are translated by half the hexagonal cell width. In our case a shift between adjacent layers can be excluded since a detailed analysis of the atomic positions of first and flat second layer shows that they are in registry.40 The AA stacking between the first and the 2F layer is further supported by the identical, within the error bar, apparent height of the two graphene sublattices reported in Figure 3f. C atoms are again imaged dark. The apparent height difference between the two C sublattices in 2F layer has a mean value of 4 ( 7 pm (vertical bar in Figure 3h). Therefore the STM data reveal a sublattice degeneracy for the 2F identical to free-standing graphene, while this degeneracy is clearly broken in the 2C layer. We note that the apparent height of 2.1 ( 0.1 Å for the 2F phase is much smaller than the theoretical value expected for AA stacking of 3.66 Å.41 However, since STM probes the local density of states (LDOS), the measured apparent height can be significantly different from the interlayer distance if the layers are differently doped. Though the spot size of the photon beam does not allow us to measure the LDOS of the two bilayers separately, ARPES measurements reveal a different charge carrier concentration for the two bilayers due to a different charge transfer toward the first graphene layer. This different doping between the layers affects the STM measurements and may result in the much lower apparent height of the 2F layer with respect to the 2C layer. The reasons that this second type of second graphene layer forms and why it needs higher ethylene exposures to form can be attributed to the following. The difference in energy between the AB and AA staking is only 20 meV/atom,39,41 with AB stacking being more stable. This difference is sufficiently small, such that the AA stacking can be stabilized by kinetic effects, which are more dominant under CVD growth with higher supersaturation. Finally, we discuss the nature of the replica bands observed for the π2C state. Figure 4a shows the first derivative of the π2C band dispersion close to the K point for the 102 L sample. Replicas may arise by
9302
2012 www.acsnano.org
CONCLUSION
Figure 4. (a) First derivative of the ARPES intensity map measured 2� off the ΓK direction of the 102 L sample. The arrows highlight a break in the band dispersion revealing minigaps at the band crossing. (b) The STM image on the same sample shows a moiré pattern with marginal longrange order of the corrugated layer (Vt = 0.88 V; It = 170 pA; T = 300 K; size 950 Å � 1060 Å).
umklapp scattering from the moiré pattern of the first graphene layer.34 Note that graphene states also display breaks in the dispersion at the band crossings (highlighted by red arrows), which reveal energy minigaps, similarly to graphene on Ir.42�44 Indeed, final state scattering enhances the photoemission intensity of the bands and may favor the resolution of the thirdorder replicas by ARPES; however, the umklapp process cannot induce minigaps. These gaps are certainly due to a periodic perturbation to the crystal potential felt by the electrons in the initial state. This is supported
METHODS Measurements were performed in three different ultrahighvacuum (UHV) chambers. The presented ARPES measurements were performed at the VUV-Photoemission beamline of the Elettra Synchrotron Facility in Trieste at 120 K, with a photon energy of 100 eV, and an energy resolution of 30 meV. The presented STM experiments were carried out at the Ecole Polytechnique Fédérale in Lausanne (EPFL) with a home-built low-temperature scanning tunneling microscope operating at 0.4 K and used for the present study at 4 K.45 Additional ARPES and STM measurements were collected at the APE-IOM beamline of Elettra. This beamline has the STM and ARPES spectrometer connected in situ, so that complementary characterization of the same surfaces can be performed. At this end station, the primary energy has been set to 65 eV, whereas the other parameters have been kept identical, and the home-built STM has been operated at 300 K. All experiments were performed under UHV conditions with a base pressure below 1 � 10�10 Torr. The Ru(0001) crystal was cleaned by repeated cycles of Arþ sputtering (E = 1200 eV) and annealing at 1500 K. The order and cleanness of the sample were monitored by lowenergy electron diffraction and photoemission spectroscopy at VUV and by STM measurements at EPFL and APE. A graphene bilayer was grown by exposing the Ru(0001) surface held at a temperature of 1600 K to 102 L (1.9 � 10�6 Torr for 53 s) of ethylene (C2H4).46 The multiphase graphene bilayers were obtained by additional exposure to 105 L (1.9 � 10�4 Torr for 530 s) of ethylene with the Ru crystal at 1600 K. Samples that have been prepared and characterized at Elettra have been transported to Lausanne and imaged in STM with atomic resolution after a flash to 800 K in a pressure of 1 � 10�10 Torr. Conflict of Interest: The authors declare no competing financial interest.
PAPAGNO ET AL.
In summary, we show evidence of a new phase of bilayer graphene on the Ru(0001) surface. Following massive ethylene exposure, ARPES spectra reveal a new π state coexisting with the known ones that is reminiscent of a different interaction with the first graphene layer. STM investigations show that the Ru surface is fully covered by the first graphene layer, which produces a strongly interacting π1 band. On top of this layer, we find two phases of second graphene layer. One of the two (2C) exhibits Bernal stacking with respect to the first layer. This layer displays weak vertical interaction and a moiré pattern with marginal long-range order, which modulates the crystal potential. This layer generates a sharp n-doped Dirac cone (π2C), replica bands, and minigaps. The other phase (2F) exhibits a single Dirac p-doped (π2F) state with nearly freestanding character. STM results show that this second-layer phase is arranged in an AA stacking sequence with respect to the first layer and has a relatively weak structural and electronic modulation. We thus prove that the first layer can be used as a template to grow different phases of graphene bilayers.
ARTICLE
by the STM measurement presented in Figure 4b, revealing that the corrugated layer exhibits a longrange moiré pattern of period ∼2.7 nm.40
Acknowledgment. This work has been supported by the European Science Foundation under the EUROCORES Program EuroGRAPHENE, by the Swiss National Science Foundation, and by the Italian Ministry of Education, University, and Research (FIRB Futuro in Ricerca, PLASMOGRAPH Project).
REFERENCES AND NOTES 1. Berger, C.; Song, Z.; Li, X.; Wu, X.; Brown, N.; Naud, C.; Mayou, D.; Li, T.; Hass, J.; Marchenkov, A. N.; et al. Electron Confinement and Coherence in Patterned Epitaxial Graphene. Science 2006, 312, 1191–1196. 2. Novoselov, K. S.; Geim, A. K.; Morosov, S. V.; Jiang, D.; Zhang, Y.; Dubonos, S. V.; Grigorieva, I. V.; Firsov, A. A. Electric Field Effect in Atomically Thin Carbon Films. Science 2004, 306, 666–669. 3. Novoselov, K. S.; Geim, A. K.; Morozov, S. V.; Jiang, D.; Katsnelson, M. I.; Grigorieva, I. V.; Dubonos, S. V.; Firsov, A. A. Two-dimensional Gas of Massless Dirac Fermions in Graphene. Nature 2005, 438, 197–200. 4. Zhang, Y.; Tan, Y. W.; Stormer, H. L.; Kim, P. Experimental Observation of the Quantum Hall Effect and Berrys Phase in Graphene. Nature 2005, 438, 201–204. 5. Ohta, T.; Bostwick, A.; Seyller, T.; Horn, K.; Rotenber, E. Controlling the Electronic Structure of Bilayer Graphene. Science 2006, 313, 951–954. 6. Novoselov, K. S.; Jiang, Z.; Zhang, Y.; Morozov, S. V.; Stormer, H. L.; Zeitler, U.; Maan, J. C.; Boebinger, G. S.; Kim, P.; Geim, A. K. Room-Temperature Quantum Hall Effect in Graphene. Science 2007, 315, 1379–1379. 7. Bostwick, A.; Ohta, T.; Seyller, T.; Horn, K.; Rotenberg, E. Quasiparticle Dynamics in Graphene. Nat. Phys. 2007, 3, 36–40.
VOL. 6
’
NO. 10
’
9299–9304
’
9303
2012 www.acsnano.org
PAPAGNO ET AL.
30.
31.
32. 33.
34.
35.
36.
37.
38.
39.
40.
41.
42.
43.
44.
45.
46.
and Rh(111) by Electronic Structure Calculations. Surf. Sci. 2011, 605, 1360–1368. Jiang, D.; Du, M.-H.; Dai, S. First Principles Study of the Graphene/Ru(0001) Interface. J. Chem. Phys. 2009, 130, 074705. Brugger, T.; Günther, S.; Wang, B.; Dil, J. H.; Bocquet, M.-L.; Osterwalder, J.; Wintterlin, J.; Greber, T. Comparison of Electronic Structure and Template Function of SingleLayer Graphene and a Hexagonal Boron Nitride Nanomesh on Ru(0001). Phys. Rev. B 2009, 79, 045407. Sutter, P. W.; Flege, J. I.; Sutter, E. A. Epitaxial Graphene on Ruthenium. Nat. Mater. 2008, 7, 406–411. Sutter, E.; Acharya, D. P.; Sadowski, J. T.; Sutter, P. Scanning Tunneling Microscopy on Epitaxial Bilayer Graphene on Ruthenium(0001). Appl. Phys. Lett. 2009, 94, 133101. Sutter, P.; Hybertsen, M. S.; Sadowski, J. T.; Sutter, E. Electronic Structure of Few-Layer Epitaxial Graphene on Ru(0001). Nano Lett. 2009, 9, 2654–2660. Enderlein, C.; Kim, Y. S.; Bostwick, A.; Rotenberg, E.; Horn, K. The Formation of an Energy Gap in Graphene on Ruthenium by Controlling the Interface. New J. Phys. 2010, 12, 033014. Vázquez de Parga, A. L.; Calleja, F.; Borca, B.; Passeggi, M. C. G., Jr.; Hinarejos, J. J.; Guinea, F.; Miranda, R. Periodically Rippled Graphene: Growth and Spatially Resolved Electronic Structure. Phys. Rev. Lett. 2008, 100, 056807. Sun, J.; Hannon, J. B.; Tromp, R. M.; Johari, P.; Bol, A. A.; Shenoy, V. B.; Pohk, K. Spatially-Resolved Structure and Electronic Properties of Graphene on Polycrystalline Ni. ACS Nano 2010, 4, 7073–7077. Rutter, G. M.; Crain, J. N.; Jarvis, E. A. A.; Stiles, M. D.; Li, T.; First, P. N.; Stroscio, J. A. Imaging the Interface of Epitaxial Graphene with Silicon Carbide via Scanning Tunneling Microscopy. Phys. Rev. B 2007, 76, 235416. Lee, J.-K; Lee, S.-C; Ahn, J.-P.; Kim, S.-C.; Wilson, J. I. B.; John, P. The Growth of AA Graphite on (111) Diamond. J. Chem. Phys. 2008, 129, 234709. Calleja, F.; Dubout, Q.; Sclauzero, G.; Pasquarello, A.; Etzkorn, M.; Lehnert, A.; Claude, L.; Gambardella, P.; Rusponi, S.; Brune, H. To be published Charlier, J.-C.; Gonze, X.; Michenaud, J.-P. First-Principles Study of the Stacking Effect on the Electronic Properties of Graphite(s). Carbon 1994, 32, 289–299. Pletikosi�c, I.; Kralj, M.; Pervan, P.; Brako, R.; Coraux, J.; N0 Diaye, A. T.; Busse, C.; Michely, T. Dirac Cones and Minigaps for Graphene on Ir(111). Phys. Rev. Lett. 2009, 102, 056808. Rusponi, S.; Papagno, M.; Moras, P.; Vlaic, S.; Etzkorn, M.; Sheverdyaeva, P. M.; Pacilé, D.; Brune, H.; Carbone, C. Highly Anisotropic Dirac Cones in Epitaxial Graphene Modulated by an Island Superlattice. Phys. Rev. Lett. 2010, 105, 246803. Papagno, M.; Rusponi, S.; Sheverdyaeva, P. M.; Vlaic, S.; Etzkorn, M.; Pacilé, D.; Moras, P.; Carbone, C.; Brune, H. Large Band Gap Opening between Graphene Dirac Cones Induced by Na Adsorption onto an Ir Superlattice. ACS Nano 2012, 6, 199–204. Claude L. Construction d'un Microscope á Effet Tunnel á Basse Température et �Etudes d'Impuretés Magnétiques en Surfaces. Ph.D. Thesis No. 3276, Ecole Polytechnique Fédérale de Lausanne 2005. Natterer, F. D.; Rusponi, S.; Papagno, M.; Carbone, C.; Brune, H. Optimizing Long-Range Order, Band Gap, and Group Velocities for Graphene on Close-Packed Metal Surfaces. J. Phys.: Condens. Matter 2012, 24, 314203.
VOL. 6
’
NO. 10
’
9299–9304
’
ARTICLE
8. Oostinga, J. B.; Heersche, H. B.; Liu, X.; Morpurgo, A. F.; Vandersypen, L. M. K. Gate-Induced Insulating State in Bilayer Graphene Devices. Nat. Mater. 2007, 7, 151–157. 9. Feldman, B. E.; Martin, J.; Yacobi, A. Broken-Symmetry States and Divergent Resistance in Suspended Bilayer Graphene. Nat. Phys. 2009, 5, 889–893. 10. Rutter, G. M.; Jung, S.; Klimov, N. N.; Newell, D. B.; Zhitenev, N. B.; Stroscio, J. A. Microscopic Polarization in Bilayer Graphene. Nat. Phys. 2011, 7, 649–655. 11. Geim, A. K.; Novoselov, K. S. The Rise of Graphene. Nat. Mater. 2007, 6, 183–191. 12. McCann, E. Asymmetry Gap in the Electronic Band Structure of Bilayer Graphene. Phys. Rev. B 2006, 74, 161403. 13. Luican, A.; Li, G.; Reina, A.; Kong, J.; Nair, R. R.; Novoselov, K. S.; Geim, A. K.; Andrei, E. Y. Single-Layer Behavior and Its Breakdown in Twisted Graphene Layers. Phys. Rev. Lett. 2011, 106, 126802. 14. Mak, K. F.; Shan, J.; Heinz, T. F. Electronic Structure of FewLayer Graphene: Experimental Demonstration of Strong Dependence on Stacking Sequence. Phys. Rev. Lett. 2010, 104, 176404. 15. Lobato, I.; Partoens, B. Multiple Dirac Particles in AA-Stacked Graphite and Multilayers of Graphene. Phys. Rev. B 2011, 83, 165429. 16. Dean, C. R.; Young, A. F.; Meric, I.; Lee, C.; Wang, L.; Sorgenfrei, S.; Watanabe, K.; Taniguchi, T.; Kim, P.; Shepard, K. L.; et al. Boron Nitride Substrates for High-Quality Graphene Electronics. Nat. Nanotechnol. 2010, 5, 722– 726. 17. Ouerghi, A.; Marangolo, M.; Belkhou, R.; El Moussaoui, S.; Silly, M. G.; Eddrief, M.; Largeau, L.; Portail, M.; Fain, B.; Sirotti, F. Epitaxial Graphene on 3C-SiC(111) Pseudosubstrate: Structural and Electronic Properties. Phys. Rev. B 2010, 82, 125445. 18. Hass, J.; de Heer, W. A.; Conrad, E. H. The Growth and Morphology of Epitaxial Multilayer Graphene. J. Phys.: Condens. Matter 2008, 20, 323202. 19. Varykhalov, A.; Sánchez-Barriga, J.; Shikin, A. M.; Biswas, C.; Vescovo, E.; Rybkin, A.; Marchenko, D.; Rader, O. Electronic and Magnetic Properties of Quasifreestanding Graphene on Ni. Phys. Rev. Lett. 2008, 101, 157601. 20. Yu, Q. K.; Lian, J.; Siriponglert, S.; Li, H.; Chen, Y. P.; Pei, S. S. Electrical Transport Properties of Wafer-Fused p-GaAs/ n-GaN Heterojunctions. Appl. Phys. Lett. 2008, 93, 112103. 21. Reina, A.; Jia, X. T.; Ho, J.; Nezich, D.; Son, H. B.; Bulovic, V.; Dresselhaus, M. S.; Kong, J. Large Area, Few-Layer Graphene Films on Arbitrary Substrates by Chemical Vapor Deposition. Nano Lett. 2009, 9, 30–35. 22. Martoccia, D.; Willmott, P. R.; Brugger, T.; Björck, M.; Günther, S.; Schlepütz, C. M.; Cervellino, A.; Pauli, S. A.; Patterson, B. D.; Marchini, S.; et al. Graphene on Ru(0001): a 25�25 Supercell. Phys. Rev. Lett. 2008, 101, 126102. 23. Preobrajenski, A. B.; Ng, M. L.; Vinogradov, A. S.; Mårtensson, N. Controlling Graphene Corrugation on Lattice-Mismatched Substrates. Phys. Rev. B 2008, 78, 073401. 24. Wang, B.; Bocquet, M. L.; Marchini, S.; Günther, S.; Wintterlin, J. Chemical Origin of a Graphene Moiré Overlayer on Ru(0001). Phys. Chem. Chem. Phys. 2008, 10, 3530–3534. 25. Marchini, S.; Günther, S.; Wintterlin, J. Scanning Tunneling Microscopy of Graphene on Ru(0001). Phys. Rev. B 2007, 76, 075429. 26. Moritz, W.; Wang, B.; Bocquet, M.-L.; Brugger, T.; Greber, T.; Wintterlin, J.; Günther, S. Structure Determination of the Coincidence Phase of Graphene on Ru(0001). Phys. Rev. Lett. 2010, 104, 136102. 27. Stradi, D.; Barja, S.; Daz, C.; Garnica, M.; Borca, B.; Hinarejos, J. J.; Sánchez-Portal, D.; Alcamí, M.; Arnau, A.; Vázquez de Parga, A. L.; et al. Role of Dispersion Forces in the Structure of Graphene Monolayers on Ru Surfaces. Phys. Rev. Lett. 2011, 106, 186102. 28. Feng, W.; Lei, S.; Li, Q.; Zhao, A. Periodically Modulated Electronic Properties of the Epitaxial Monolayer Graphene on Ru(0001). JPCC 2011, 115, 24858–24864. 29. Iannuzzi, M.; Hutter, J. Comparative Study of the Nature of Chemical Bonding of Corrugated Graphene on Ru(0001)
9304
2012 www.acsnano.org
